Facade Thermal Inspection ever wondered if your facade’s thermal efficiency is at its peak? Could warm edge spacers be the missing piece? Using thermal cameras, we detect temperature variations along the glass and aluminum edges to uncover hidden heat loss.
Why we do this? Let’s understand why warm edge spacers are crucial in double glass units (DGUs) of curtain wall systems:
1. Improved Thermal Insulation
Warm edge spacers are made from materials with low thermal conductivity, such as plastic. Composites or stainless steel. Unlike traditional aluminum spacers, which are highly conductive, warm edge spacers. Reduce the amount of heat transferred through the edge of the glass. This helps to maintain a consistent indoor temperature, improving the overall energy efficiency. Of the building.
2. Condensation Reduction
Because warm edge spacers minimize heat loss at the glass edge, the interior surface. Of the glass remains warmer. This reduces the likelihood of condensation forming on the inside of the window. Which is particularly important in curtain wall systems. Lower condensation means less risk of mold growth, water damage. And corrosion, which can compromise the durability and appearance of the facade.
3. Enhanced Comfort
With warm edge spacers, there is less temperature variation across the glass surface. This creates a more comfortable indoor environment by reducing cold drafts near the windows. It also helps to prevent the “cold wall effect,” where occupants. Feel uncomfortable due to cold temperatures radiating from the glass.
4. Energy Efficiency and Cost Savings
By improving the thermal performance of curtain wall systems, warm edge spacers contribute to lower energy consumption for heating and cooling. This results in cost savings for building owners and operators. The improved insulation can also help meet building energy codes and standards for sustainability.
In summary, warm edge spacers play a significant role in increasing the energy efficiency, durability, and comfort of curtain wall systems by reducing thermal bridging, minimizing condensation, and maintaining the performance of double glass units over time.